JP3910513B2 - Production system using infrared rays - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a production system that enhances the production effect of the event by causing the production equipment carried by each spectator to perform operations such as light emission and vibration during an event such as a concert or an outdoor show, The present invention relates to an effect system using infrared rays that transmits a control signal by infrared rays to cause a director to execute a predetermined operation.
[0002]
[Prior art]
At events such as concerts and shows regularly held in an amusement park, the event audience carries stickers, accessories, and other lighting equipment with display light-emitting elements, and the display light-emitting elements blink during the event. And the effect is enhanced.
[0003]
In particular, a stage device carried by a large number of spectators will be more effective when the display light-emitting elements blink simultaneously with the progress of the event, so a transmission device will be installed around the viewing area where the spectators will gather. Japanese Unexamined Patent Application Publication No. 2000-260212 discloses an effect system that transmits a control signal for controlling the operation of the effect tool from the device and controls blinking of the display light emitting element of the effect tool.
[0004]
FIG. 8 shows this conventional production system 100, and a transmitting device 102 that transmits a control signal is arranged around a viewing area 101.
[0005]
The transmission device 102 is connected to a plurality of transmission antennas 103A and 103B arranged around the viewing area 101 by the communication cable 104, and is transmitted from the transmission device 102 when the switch 102a provided in the transmission device 102 is pressed. Control signals are transmitted to the transmitting antennas 103A and 103B, and radio waves including the control signals are transmitted from the transmitting antennas 103A and 103B.
[0006]
A spectator gathered to watch an event in the viewing area 101 includes a receiving unit that receives radio waves including a control signal, and a display device that includes a display light-emitting element (none of which is shown) that is controlled to blink by the control signal. 105, 105 ... are carried.
[0007]
When the event progressor presses the switch 102a of the transmitting device 102 at a predetermined timing in accordance with the progress of the event, a radio wave including a control signal is transmitted to the viewing area 101, and display lights 105, 105,. The elements blink simultaneously with the control signal.
[0008]
Therefore, since the stage effector 105 carried by the audience blinks as the event progresses, the audience can have a sense of unity with the event director side, and a high stage effect can be obtained.
[0009]
[Problems to be solved by the invention]
However, in this conventional production system 100, the production tool 105 needs to be provided with a receiving unit that receives radio waves including a control signal and does not malfunction due to other radio waves. In particular, in this type of production system 100, the production effect increases as the number of production devices 105 blink simultaneously. However, the production device 105 becomes expensive, and many audience members can carry the production device 105. There was no problem.
[0010]
In addition, since the director works only in the event, it is only useful as a figurine after the audience brings it home, and an expensive director that has a reception function for the spread of the conventional director system 100. It was an obstacle.
[0011]
In addition, since radio waves are transmitted to all the production tools 105 in the viewing area 101, it is necessary to transmit with high antenna power, and there is a possibility that harmonics thereof become noise and are superimposed on the signal lines of the audio equipment used for the event. is there.
[0012]
Further, when the viewing area 101 is several hundred meters wide, the length of the communication cable 104 that connects the transmitting device 102 and the transmitting antennas 103A and 103B increases, and the control signal is transmitted to the transmitting antenna 103A by the resistance and capacitive reactance of the wires. , 103B is delayed until it cannot be ignored. As a result, transmission antennas 103A and 103B having different lengths of the communication cable 104 up to the transmitting device 102 transmit radio waves including control signals that are out of phase, and in the effector 105 that receives the respective radio waves, the control signal This causes a problem that it cannot be demodulated.
[0013]
The present invention has been made in view of such a problem, and provides an effect system using infrared rays that can manufacture each device and effect tool constituting the system at a relatively low cost.
[0014]
In addition, an effect system using infrared rays that does not affect the operation of other devices installed in the event is provided.
[0015]
Moreover, even if the viewing area is wide, an effect system using infrared rays that reliably controls the operation of each effector is provided.
[0016]
[Means for Solving the Problems]
An effect system using infrared rays according to the invention of claim 1 is arranged in a plurality of positions in or around a viewing area of an event performed outdoors or indoors at night, and directs infrared signals including control signals to the viewing area. An infrared signal light emitting unit that emits light, and a director that receives the infrared signal and performs a predetermined operation by a control signal included in the infrared signal, and at a predetermined timing according to the event An effect system using infrared light that emits an infrared signal and causes each effector carried by a large number of spectators in a viewing area to execute a predetermined operation by a control signal included in the infrared signal,
The infrared signal emitted from the infrared signal light emitting unit is substantially equal to the carrier frequency of the remote control signal used for remote control of home appliances. 38kHz ± 2kHz Infrared carrier of frequency, Includes a reader code that identifies the remote control signal A modulated signal obtained by amplitude-modulating the control signal, When the demodulated signal demodulated from the infrared signal having a frequency of 38 kHz ± 2 kHz includes the leader code, the director performs a predetermined operation according to the control signal, does not include the leader code, Even if it matches the remote control signal, a predetermined operation is executed. It is characterized by that.
[0017]
Since the control signal is transmitted using an infrared carrier wave having a frequency substantially equal to the carrier frequency of the remote control signal used for remote control of home appliances, the infrared light emitting unit that emits the infrared signal and the infrared signal are received. A general-purpose infrared transmission / reception circuit and modulation / demodulation element can be used for each of the directors, and the entire director system can be constructed at a low cost.
[0018]
In addition, a stage device that receives an infrared signal can also receive a remote control signal for remotely controlling home appliances and demodulate it into a predetermined remote control signal, so that when a remote control signal is received, a predetermined operation is performed. Can be executed.
[0019]
The light receiving unit of the stage that receives infrared signals is night and indoor, so it will not saturate when receiving sunlight, will not malfunction, and the infrared signal will affect the operation of other equipment used for the event. There is nothing.
[0020]
In the production system using infrared rays according to the invention of claim 2, the infrared signal light emitting section whose distance to the position of the viewing area where the infrared signal is to be reached is D, the arrival distance of the infrared signal is d A number of light emitting diodes are arranged on the substrate, and at least (D / d) on the substrate. ² Infrared signals are emitted simultaneously from the light emitting diodes toward the viewing area.
[0021]
An infrared signal emitted from the light emitting diode at a luminous intensity I is received by the light receiving element and d is a limit distance that can be detected, and an illuminance of the infrared signal received by the light receiving element at a distance d from the light emitting diode 9 at that time is E. Then, E = I / d from the law of inverse squares ² It is represented by On the other hand, it is necessary to use a light source having a light intensity IS of S times in order to reach an infrared signal at a position away from the viewing area by a distance D using the same light receiving element capable of detecting an infrared signal with illuminance E. Yes, E = SI / D ² It is represented by Therefore, I / d ² = SI / D ² (D / d) of luminous intensity I emitted from one light emitting diode ² If a light source having double the luminous intensity is used, the infrared signal reaches a position away from the light source by a distance D. Since the distance between the plurality of light emitting diodes arranged on the substrate is negligibly short with respect to the distance D to the viewing area, it is regarded as a point light source, and (D / d) ² The intensity of the infrared signal emitted simultaneously from the light emitting diodes is (D / d) ² Doubles and reaches a position separated by distance D.
[0022]
As a result, even if the directivity angle of each light-emitting diode is limited, it is possible to reach infrared signals over long distances, so that the infrared signals can reach the effectors that the audience has individually in a wide viewing area. Can be made.
[0023]
In the production system using infrared rays according to the invention of claim 3, each infrared signal light emitting unit disposed at a plurality of positions is optically connected to a common transmission control unit that transmits a control signal at a predetermined timing according to the event. A control signal transmitted from the transmission control unit is optically transmitted to each infrared signal light emitting unit via an optical fiber.
[0024]
Even if the distance between the common transmission control unit and each infrared signal light emitting unit is different, the control signal arrives simultaneously with each infrared signal light emitting unit. Even in the case of receiving, an infrared signal having the same phase can be received. Therefore, not only there is no demodulation error, but each infrared signal is synthesized even if the light amount is weak, and the control signal can be easily demodulated.
[0025]
The effect system using infrared rays according to the invention of claim 4 is characterized in that the effector includes a plurality of display light emitting elements, and a specific display light emitting element is controlled to be turned on or off by a control signal.
[0026]
A stage tool used for an event performed at night or indoors stands out by controlling blinking of the light emitting element for display, and can provide an effective stage.
[0027]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment of the present invention will be described with reference to FIGS.
[0028]
FIG. 1 is an explanatory diagram showing a schematic configuration of an effect system 1 using infrared rays according to an embodiment of the present invention. In this embodiment, the production system 1 using infrared rays is adopted for a show event held at night in an amusement park square, and includes a control room 2 and a plurality of long-distance infrared signal light emitting units. 3A, 3A, and a plurality of wide directivity infrared signal light emitting units 3B, 3B, and optical fiber cables 4, 4,... Connecting these infrared signal light emitting units 3A, 3B to the control chamber 2 And a plurality of directors 5, 5..
[0029]
The control room 2 serves as a transmission control unit that transmits a control signal at a predetermined timing in accordance with the progress of the event. For example, each time a bass sound that is played during a show performance is detected, A control signal which is an envelope of any of the signals A, B and C in FIG. 7 is converted into an optical signal and sent to the optical fiber cable 4.
[0030]
In addition to this example, the timing at which the control signal is transmitted may be such that an operator on the event organizer side operates a switch (not shown) according to the progress of the event to transmit the control signal.
[0031]
The control signal is a pulse waveform signal in which a 3-bit data code is subjected to pulse distance modulation (pulse pitch modulation) that varies the L-level time width for each bit data, and a leader code and stop bits are combined before and after that to form one frame. In this case, any one of the three types of signals A, B, and C having different data codes is selected and transmitted according to the contents for controlling the production tool 5.
[0032]
For example, a signal A having a data code of (0, 0, 1) is a control signal for controlling lighting of a group A LED (6A) (see FIG. 5), which will be described later, provided in the effector 5, and the data code is A signal B of (0, 1, 0) is a control signal for controlling lighting of a group B LED (6B) (see FIG. 5), which will be described later, provided in the effector 5, and the data code is (0, 1, 0). The signal C in 1) is a control signal for controlling lighting of the LEDs A and B (6A, 6B).
[0033]
The leader code distinguishes the infrared signal used in this production system from other infrared signals such as natural light, and infrared light emitted from the infrared signal light emitting units 3A and 3B when an event is being performed. The time width of the H level and the L level is set to a combination unique to this system so that the director 5 can identify and operate only the signal. Here, as shown in FIG. 7, the combination of the L level of 2 msec width following the H level of 3 msec width is used as the leader code.
[0034]
Each bit data of the data code is always assigned an H level with a time width of 600 usec. When the bit data is “1”, an L level with a time width of 600 usec follows the H level, and the bit data is In the case of “0”, the L level having a time width of 1200 usec continues.
[0035]
As shown in FIG. 1, the long-distance type infrared signal light emitting unit 3A and the wide directivity type infrared signal light emitting unit 3B are adjacent to the stage where the show is held and are expected to gather for the audience to watch the show. The infrared signals emitted from these light emitting units 3A and 3B reach the entire area without leaks, and are arranged in the viewing area and at necessary places around it.
[0036]
As shown in FIG. 2, the long-distance infrared signal light emitting unit 3A has five printed wiring boards 8 mounted on an arcuate frame 7 at intervals of 30 degrees on the circumference. 8, 280 infrared light emitting diodes 9 are mounted in a matrix of 28 rows and 10 columns facing outward.
[0037]
In general, an arrival distance of the infrared light emitting diode 9 that emits an infrared signal of luminous intensity I (a limit distance at which the infrared signal can be received by the light receiving element) is d, and the red light received by the light receiving element away from the light emitting diode 9 by the distance d. If the illuminance of the external signal is E, E = I / d from the inverse square law. ² It is represented by On the other hand, in order to use the same light receiving element that can detect the infrared signal with the illuminance E and to reach the infrared signal at a position separated by the distance D, it is necessary to use a light source having a luminous intensity IS of S times. SI / D ² It is represented by Therefore, I / d ² = SI / D ² In order for the infrared signal to reach a position away from the light source by a distance D, (D / d) of the luminous intensity I emitted from one infrared light emitting diode 9 ² It is necessary to use a light source with double luminous intensity.
[0038]
On the other hand, the vertical and horizontal width of the printed wiring board 8 which is the size of the rectangular light source is so small that it can be ignored with respect to the reach D of the infrared signal to reach the viewing area. The emitted light source is regarded as a point light source, and (D / d) ² If the infrared light emitting diodes 9 are arranged, approximately (D / d) ² Double luminous intensity is obtained.
[0039]
Here, the axial reach distance d of an infrared signal emitted from one infrared light emitting diode 9 is 10 m, and 280 times the luminous intensity is obtained by arranging 280 infrared light emitting diodes 9. Assuming that an infrared signal can reach a distance of about 167 m in the orthogonal direction of one printed wiring board 8. Actually, since the infrared light emitting diode 9 used in the long-distance type infrared signal light emitting unit 3A has a fixed directivity angle, about half of the infrared light emission mounted on the adjacent printed wiring board 8 is used. Since the infrared signal emitted from the diode 9 is also received and a luminous intensity of about 560 times is obtained, the infrared signal can reach an area about 236 m away from the light source. As a result, an infrared signal can be transmitted to a large number of stage tools 5 in a wide viewing area even when using the infrared light emitting diode 9 having a relatively narrow directivity angle. Accordingly, as shown in FIG. 1, a plurality of the long-distance infrared signal light emitting units 3A are arranged at relatively high places around the viewing area.
[0040]
As shown in FIG. 3, the wide directivity type infrared signal light emitting unit 3 </ b> B includes ten vertically long printed wiring boards 11 on a columnar mounting frame 10 at intervals of 36 degrees along the circumferential direction. The 28 infrared light emitting diodes 12 are mounted on each printed wiring board 11 along the longitudinal direction thereof.
[0041]
The infrared light emitting diode 12 has a low directional intensity in the axial direction as compared with the infrared light emitting diode 9 used in the long-distance infrared signal light emitting unit 3A, but has a wide directivity angle. By arranging them all around the circumference, infrared signals are emitted without leakage around the periphery.
[0042]
Therefore, as shown in FIG. 1, the wide directional angle type infrared signal light emitting unit 3B includes a plurality of wide directional angle type infrared signal light emitting units 3B in the viewing area so as to compensate for the area where the infrared signal of the wide directional angle type infrared signal light emitting unit 3B cannot reach. Be placed. The wide directivity angle type infrared signal light emitting unit 3B emits an infrared signal from a relatively low position, so that it is surely applied to, for example, the staging device 5 of an infant that becomes a shadow of an adult and is difficult to reach the infrared signal. Infrared signal can be reached.
[0043]
Each long-distance type infrared signal light emitting unit 3A and wide directivity type infrared signal light emitting unit 3B, when receiving a control signal transmitted from the control room 2, pulse with a carrier wave having a carrier frequency within a range of 38 kHz ± 2 kHz. The control signal, which is a signal, is amplitude-modulated and transmitted simultaneously from each of the infrared light emitting diodes 9 and 12 as an infrared signal. An infrared carrier wave having a frequency of 38 kHz ± 2 kHz is made to coincide with a carrier frequency of a remote control signal transmitted from a remote control transmitter (hereinafter referred to as a remote controller) for remotely controlling a home appliance such as a television receiver or an air conditioner. Thus, by making the frequency of the infrared carrier wave coincide with each other, the light receiving element, the light emitting element, the modulation / demodulation element and the like for remote control that are used for general purposes are used as they are for each element of the effect system according to the present invention. The production tool 5 and the infrared signal light emitting unit 3 can be formed at a very low cost. Further, the director 5 can be taken home and a predetermined operation can be performed by a remote controller in the home.
[0044]
Each long-distance type infrared signal light emitting unit 3A or wide directivity type infrared signal light emitting unit 3B is connected to the control room 2 via the optical fiber cable 4 to simultaneously receive the transmitted control signal. .
[0045]
As described above, in the present invention, each long-distance type infrared signal light emitting unit 3A or wide directivity type infrared signal light emitting unit 3B is arranged in a distributed manner at a plurality of locations in or around the viewing area. There is a difference of several hundreds meters between the infrared light emitting units 3A and 3B in the distance from the control room 2 installed at one position. As in the conventional case, if the capacitance reactance per 100 m is connected using an electric wire with a resistance of 10000 pF and a resistance of 1 KΩ, a time difference of 10 usec per 100 m occurs in the arrival time of the control signal. As a result, when the plurality of infrared signal light emitting units 3A and 3B receive the control signal and transmit the infrared signal, the director 5 converts the infrared signal having a time difference of 10 usec per 100 m into the plurality of infrared signals. The signals are simultaneously received from the signal light emitting units 3A and 3B.
[0046]
For example, if the infrared carrier wave of the infrared signal is 40 kHz, a plurality of infrared signals having a phase difference of 10 usec or more are superimposed on the infrared signal having a period of 25 usec, and the effector 5 cannot be demodulated at all. It will be a thing.
[0047]
In the present embodiment, the control signal transmitted from the control room 2 simultaneously reaches each long-distance type infrared signal light emitting unit 3A or the wide pointing angle type infrared signal light emitting unit 3B through the optical transmission line by the optical fiber cable 4. The transmission of infrared signals is synchronized.
[0048]
The stage device 5 carried by the spectator is, for example, a stick shape shown in FIG. 4, and includes an infrared light surrounded by a star-shaped light emitting operation unit 13 at one end and a cylindrical infrared filter at the base end of the light emitting operation unit 13. An operation switch 15 is provided on the light receiving portion 14 and a stick-like grip portion. The light emitting operation unit 13 includes six A group light emitting diodes 6A at each of the star positions in a translucent star cover, and five B group light emitting diodes on the circumference in the center of the star shape. 6B is attached.
[0049]
FIG. 5 is a block diagram showing the configuration of the production tool 5, and the photodiode 16 arranged in the infrared light receiving unit 14 receives the infrared signal emitted from the infrared signal light emitting units 3 </ b> A and 3 </ b> B. The infrared signal is photoelectrically converted by the photodiode 16 and then converted into a voltage by a current-voltage conversion circuit 17 connected to the subsequent stage, and a received signal matching the carrier frequency is extracted by a band-pass filter 18. The received signal is extracted by the waveform shaping circuit 19 including an envelope follower, and the envelope is extracted and converted into a demodulated signal. Each circuit from the photodiode 16 to the waveform shaping circuit 19 can use a general-purpose light receiving IC provided in a home electric appliance whose operation is controlled by a remote controller.
[0050]
The demodulated signal output from the waveform shaping circuit 19 is input to the control circuit unit 20. The control circuit unit 20 is connected to the operation switch 15, six light emitting diodes 6 </ b> A in the A group, and five light emitting diodes 6 </ b> B in the B group. Each circuit in the production tool 5 except for the operation switch 15 is driven by a dry battery (not shown) built in the production tool 5 as a power source.
[0051]
The control circuit unit 20 decodes the control signal included in the demodulated signal, controls the blinking of the group A light emitting diodes 6A and the group B light emitting diodes 6B by the control signal, and performs another control by the operation switch 15. Hereinafter, the operation will be described with reference to the flowchart of FIG.
[0052]
In the stand-by state of the director 5 in which neither the infrared signal nor the switch input by the operation switch 15 is detected, the loop consisting of step S1 for determining the infrared signal input and step S2 for determining the switch input is repeated. do not do.
[0053]
If there is a switch input by the operation switch 15, the process proceeds from step S2 for determining the switch input to step S3, and the light-emitting diodes A and B of the group A are alternately blinked. Therefore, while the event is not being performed, by operating the operation switch 15, the inside and outside of the star shape of the light emitting operation unit 13 alternately flash.
[0054]
After starting the blinking operation, a timer of, for example, about 5 seconds is set in step S4, and the blinking operation continues until the set timer overflows.
[0055]
When the timer overflows, the process proceeds from step S5 to step S6, the light emitting diodes A and B are controlled to be turned off, and the standby state is restored.
[0056]
When the input of the infrared signal is determined in the standby state, the process proceeds from step S1 to step S7. The input determination of the infrared signal is performed by determining whether the frequency of the infrared carrier wave is 38 kHz ± 2 kHz. In the block diagram of FIG. 5, the control circuit unit 20 inputs the demodulated signal of the pulse waveform. When it is determined that an infrared signal has been input. Therefore, Director 5 The process proceeds from step S1 to step S7 not only when receiving an infrared signal during the event but also when receiving a remote control signal from the remote control.
[0057]
Prior to step S2 for discriminating switch input, input of an infrared signal is discriminated in step S1, so that there is no switch input while the infrared signal is transmitted during the event or the remote control is operated. However, the operation in step S3 is not performed. Thus, control by the control signal and control by the remote control are prioritized so that only the specific director 5 does not blink during the event.
[0058]
In step S7, whether or not the infrared signal whose input has been determined is emitted from the infrared signal light emitting units 3A and 3B during the event is determined based on the presence or absence of a leader code. If the demodulated signal does not have a leader code consisting of a combination of a 3 msec wide H level and a 2 msec wide L level, it is determined as another infrared signal emitted from a remote controller or the like, and the process proceeds to step S8. In step S8, it compares with the existing various remote control signals, and if it matches any one, the process proceeds to step S9, and the light emitting diodes 6A and 6B are controlled to blink randomly. Thereby, the director 5 can be taken home and used as a toy for flashing the light-emitting diodes 6A and 6B with a remote controller for controlling home appliances.
[0059]
After the blinking operation is started, the operation is continued during the timer set period by steps S4, S5, and S6 as in the processing from step S3, and the process returns to the standby state.
[0060]
If it is not discriminated from the control signal of the remote control in step S8, it is regarded as erroneous recognition due to noise, and after a timer set period is passed through steps S4, S5, and S6, the process returns to the standby state.
[0061]
If it is determined in step S7 that the infrared signal is emitted from the infrared signal light emitting units 3A and 3B during the event, the data code included in the demodulated signal is further detected in steps S10, 11 and 12. Is compared with the data codes A, B, and C, and if they match each other, a predetermined operation shown in steps S13, 14, and 15 is executed.
[0062]
The operations of the director 5 in steps S13, S14, and S15 are executed simultaneously by all the directors 5 in the viewing area, so that the timing of the music played in the viewing area can be adjusted to a predetermined timing during the event. The light-emitting diodes 6A and 6B of all the production tools 5 flash simultaneously according to the call of the presenter, so that each spectator can participate in the progress of the event with a sense of unity.
[0063]
In the above embodiment, the blinking control of the light-emitting diodes 6A and 6B is performed on the effector 5 possessed by the spectator at an event performed outdoors or indoors at night. Is particularly effective. However, for example, the operation executed in response to the control signal is not limited to the blinking operation of the light emitting diodes 6A and 6B, and for example, a predetermined sound may be emitted from the effector 5 or may be vibrated.
[0064]
In addition, the event viewing area has been described as an example where it is concentrated in one place. However, the event viewing area is distributed over a plurality of viewing areas, and an infrared signal including a control signal is sent to each viewing area to execute an operation based on the control signal. It may be. For example, in an amusement park in which a plaza that hosts an event such as a show and an amusement park in which a spectator rides on a game device and develops various events, etc., the director 5 operated at the show event can be used at other attractions. Can also be controlled.
[0065]
Further, as long as the control signal is included in the infrared signal and transmitted, the modulation method is not limited to the modulation method according to the above-described embodiment, and other modulation methods may be used.
[0066]
Furthermore, the production tool 5 is not limited to the stick shape as described above, and may have various shapes, and the production tool 5 may be provided with the functions described above in accessories and batches worn by the audience.
[0067]
【The invention's effect】
As described above, according to the first aspect of the present invention, the directors possessed by the audience perform predetermined actions all at once in synchronization with music and attractions, so that the audience can participate in a sense of unity with the progress of the event. .
[0068]
By arranging multiple infrared signal emitters in and around the venue, it is possible to ensure that infrared signals can reach even the staging equipment of short infants, etc. There is no risk of affecting the operation of the electronic equipment used.
[0069]
The director does not need to be provided with a receiving unit that receives radio waves, and can use a light receiving element and a demodulating element that are widely used as a home remote control, and can be manufactured at low cost.
[0070]
Furthermore, since the director can be used as a toy that operates with the remote control transmitter even after being taken home, the director can be used and the director system can be further spread.
[0071]
According to the invention of claim 2, since a large number of light emitting diodes are concentrated on the substrate, the power of the infrared signal is increased, and the infrared signal can reach a long distance of several hundred meters. .
[0072]
As a result, even if the directivity angle of each light-emitting diode is limited, infrared signals can be made to reach each director having a large number of audiences in a wide viewing area at the same time.
[0073]
According to the invention of claim 3, even if the control signal has a high frequency, there is no transmission delay as compared with the case of using an electric wire, and the infrared signal light emitting units are separated by an interval of several hundred meters. Infrared signals can be emitted simultaneously. Therefore, the control signal can be demodulated even if the effector receives infrared signals from a plurality of infrared signal light emitting units.
[0074]
According to the invention of claim 4, in addition to the effects of these inventions, the display light emitting element of the stage tool used for an event to be performed at night or indoors is controlled to blink, so that the operation is more effective and effective. Can produce.
[Brief description of the drawings]
FIG. 1 is an explanatory diagram showing an outline of an effect system using infrared rays according to an embodiment of the present invention.
FIG. 2 is a perspective view of a long-distance infrared signal light emitting unit 3A.
FIG. 3 is a perspective view of a directional angular infrared signal light emitting unit 3B.
FIG. 4 is a front view of the production tool 5;
FIG. 5 is a block diagram showing a configuration of the production tool 5; .
6 is a flowchart showing the operation of the control device 20 of the production tool 5. FIG.
FIG. 7 is a waveform diagram showing waveforms of a control signal included in a remote control signal and an infrared signal.
FIG. 8 is an explanatory diagram showing an outline of a conventional effect system 100. FIG.
[Explanation of symbols]
1 Production system using infrared rays
2 Control room (transmission control unit)
3A long-distance infrared signal light emitting unit (infrared signal light emitting unit)
3B Wide directivity type infrared signal light emitting part (infrared signal light emitting part)
4 Optical fiber
5 Director
6A Group A LED (light-emitting element for display)
6B Group B LEDs (light-emitting elements for display)
9 Infrared light emitting diode (light emitting diode)

Claims (4)

Infrared signal light emitting units (3A, 3B) that are arranged at a plurality of positions in or around a viewing area for events that are performed outdoors or indoors at night, and emit infrared signals including control signals toward the viewing area;
A director (5) that receives an infrared signal and executes a predetermined operation by a control signal included in the infrared signal,
Infrared signals are emitted from the infrared signal light emitting sections (3A, 3B) at a predetermined timing according to the event, and are included in the infrared signals in each effect tool (5) carried by many spectators in the viewing area. An effect system that uses infrared rays to execute a predetermined operation according to a control signal,
Infrared signal emitted from the infrared signal emitting unit (3A, 3B) is a infrared carrier having substantially the same 38 kHz ± 2 kHz frequency to the carrier frequency of the remote control signal used for remote control of home appliances, the remote control signal and A modulated signal obtained by amplitude-modulating a control signal including a leader code to be identified ,
When the demodulated signal demodulated from the infrared signal having a frequency of 38 kHz ± 2 kHz includes the leader code, the director (5) performs a predetermined operation according to the control signal, and does not include the leader code. An effect system using infrared rays , wherein a predetermined operation is executed even when the remote control signal matches any one of the remote control signals . In the infrared signal light emitting section (3A) having a distance D to the position of the viewing area where the infrared signal is to reach, the light emitting diode (9) having an infrared signal reaching distance d is disposed on the substrate. Many are arranged,
The effect using infrared rays according to claim 1 , wherein infrared signals are emitted simultaneously from at least (D / d) ^two light emitting diodes (9) on a substrate toward the viewing area. system. Each infrared signal light emitting section (3A, 3B) arranged at a plurality of positions is connected by a fiber optic (4) to a common transmission control section (2) that transmits a control signal at a predetermined timing according to the event,
The infrared signal according to claim 1, wherein a control signal transmitted from the transmission control unit (2) is optically transmitted to each infrared signal light emitting unit (3A, 3B) via an optical fiber (4). Production system.   The production tool (5) includes a plurality of display light emitting elements (6A, 6B), and controls the specific display light emitting elements (6A, 6B) to be turned on or off by a control signal. 4. A production system using infrared rays according to any one of items 3.

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